Cathode elements for a hall-héroult cell for aluminium production and a cell of this type having such elements installed

ABSTRACT

A cathode element (1′) for an electrolysis cell of Hall-Heroult type for producing aluminium, comprises a body (4) of calcinated carbonaceous material connected with the upper side of a metallic collector plate (2). A space between the said carbonaceous body and the collector plate being filled with an electric conductive material preferably comprising conductive particles. The collector plate (2) further can comprise at least one horizontal outlet (5, 5′) on at least one side and/or at least one vertical metallic current outlet (7) connected to the lower side of the collector plate (2). In one embodiment the collector plate is divided in two sections (20; 20). The invention also relates to a cell of Hall-Heroult type utilizing such cathode elements (1).

The present invention relates to cathode elements for a Hall-Héroult cell for aluminium production and a cell of this type having such elements installed.

Commonly, cathode elements for aluminium production cells are made of pre-baked cathode blocks or bodies of a calcined carbonaceous material, the bodies having preformed grooves or slots in the bottom thereof that allow current leads such as collector bars to be entered into them and rodded to it. The space between the wall of the slots and the bars can commonly be filled with melted cast-iron or a contacting paste or glue for the fixation of said collector bars. Several cathode elements are installed in the cell and form together the cathode.

In accordance with the Applicants own WO2009/099335A1 there is applied electric conductive particles as a fill-in material between the electrical current conductor and the carbonaceous body of calcinated carbonaceous material in an electrode. The use of electric conductive particles without a hardening matrix facilitates mobility of the conductive particles for electric current when the geometry changes over time e.g. due to thermal expansion. The electrical resistance in a cathode element where such particles is applied has been observed to be improved with reference to commonly used contact paste or melted cast-iron. In FIG. 9 of said WO-document it is disclosed an end-view of a cathode block having recesses or slots in its lower part. There are arranged collector elements into the slots, where the remaining space is filled with electric conductive particles. The collector elements are fixed to a collector plate that collects the current and that further secures stability of the cathode element and gives additional contact area.

The present invention relates to cathode elements based upon collector plates with carbonaceous bodies where it is included several novel and inventive features in the construction thereof. Some main elements are related to;

-   -   horizontal current outlets (HO)     -   vertical current outlet(s) (VO)     -   conductor elements and their extension in combination with use         of electric insulation and protective sheet material     -   fixation of conductor elements     -   arrangement of the current outlets with regard to the collector         plates of the cathode elements.

According to a characteristic feature of claim 1, the collector plate can comprise at least one horizontal current outlet on at least one side and/or at least one vertical metallic current outlet connected to the collector plate.

Advantageously the collector plate can be planar without protruding collector elements and the carbonaceous body can be without matching slots, the rodding material simply forms a layer of electric conductive material, that may comprise electrical conductive particles (0-100 wt %), arranged in a space between the collector plate and the carbonaceous body.

In an embodiment of the invention, the carbonaceous body is rodded to the collector plate in a manner where the outer end part of the carbonaceous body is electrically insulated from the collector plate, at a distance up to 450 mm from the end thereof and inwards.

In one other embodiment, the carbonaceous body is rodded to the collector plate in a manner where the outer end parts of the carbonaceous body are electrically insulated from the collector plate at different lengths on the two ends of the plate (asymmetric configuration).

In one embodiment, at least one thermocouple (TC) is inserted into a metallic component inside of or below the collector plate to be able to monitor the temperature at that location.

In one other embodiment, the at least one horizontal current outlet is integrated with the collector plate.

In a further embodiment, it is integrated in a slot in said collector plate.

In another embodiment, the horizontal current outlet comprises one current conductor part integrated with the collector plate by a press-fit (knock) fixation in a recess of the collector plate that is complementary with a corresponding part of the conductor.

In one embodiment, the part of the current conductor integrated to the collector plate has a delta shaped part.

In a further embodiment, it comprises at least one horizontal current outlet on each end being integrated with the collector plate.

In one embodiment, the cross section of or the insertion length of the horizontal current outlet at one end is different to that of the other end (asymmetric).

In still another embodiment the current outlet comprises a copper conductor preferably covered by a protective sheet material.

In one embodiment, there is arranged at least one vertical current outlet at the opposite side of the collector plate than the carbonaceous body.

There is one embodiment where the vertical outlet comprise a socket integrated with the collector plate wherein a rod-shaped current conductor is attached to the socket.

In one embodiment, the socket can be of metallic material and welded to the collector plate.

In a further embodiment, has an internal recess where an upper part of the current conductor has a shape complementary with said recess for fixation of said current conductor to the socket.

In one embodiment, the fixation is a press-fit (knock) fixation.

In one other embodiment, the socket has internal threads at its outermost end for receiving a sleeve with complementary external threads, wherein the sleeve surrounds the current conductor and where the end of the sleeve abuts an annular flange or ring at the current rod for forcing the rod into the socket when tightened.

In still another embodiment, there is a threaded bolt at the top of the socket communicating with a threaded bore.

In one embodiment, the current conductor is made out of copper or an alloy thereof.

In one other embodiment, at least one metallic collector element is arranged at the upper side of a metallic collector plate, where said collector element is embedded in a corresponding recess in the bottom part of the carbonaceous body, the recess being wider than the collector element and being filled with an electric conductive material comprising conductive particles.

In another embodiment, there are one or more collector elements, preferably 3 to 7 being separated at a distance of typically 50 mm to 150 mm.

In still another embodiment, the at least one collector element(s) is of same length or shorter length than the carbonaceous body.

According to one characteristic feature of claim 23, an electrolysis cell of Hall-Héroult type can comprise several cathode elements of the invention where the cell is built with several cathode elements and in a configuration of only the same type of elements.

According to one other characteristic feature of claim 24, an electrolysis cell of Hall-Héroult type can comprise several cathode elements of the invention where the cell is built with several cathode elements and in a configuration of different elements.

Advantageously, the collector plate can have one to five inserts of materials with higher electric conductivity, like copper.

Preferably, the collector plate can have horizontal outlets (HO) made from steel or copper or some similar good conducting material reaching out of the cathode shell to allow a connection to the cathode flexibles.

Advantageously, each collector plate can have none, one or two HOs on each end and according to a different aspect, the HOs can be of rectangular or round cross section. Preferably, the HO can be inserted into a slot (groove) in the plate from top, which can be closed with a welded steel plate from top, or into open space from the side of the plate, preferably when a round cross-section is applied.

Advantageously, the HOs can be attached to the plate by welding, mechanical press fitting, thermal press fitting, knock-in cones, threads, or a combination of those to get a strong mechanical and electric feasible connection.

Preferably, the HO can be attached to a delta-shaped insert of good conducting material, like copper, to allow a low-resistance for the current flow.

Advantageously, the HOs can be connected to the cathode flexes by welding or clamps.

Preferably, the HOs on both side of the collector plate can have different cross section and insertion depth into the plate to allow a specific electric resistance on each side.

Advantageously, the HOs can be long enough to reach out of the cathode shell, or they are short enough to allow a vertical placement of the cathode assembly into the cathode lining.

Preferably, there is a round or rectangular opening for each HO in the steel shell.

Advantageously this opening is sealed with a steel frame, a sealing rope and a plate, which is fixed to press on the sealing rope ensuring a tight sealing between shell and HO.

Preferably, one or more VOs can be attached to each cathode assembly from the bottom side to conduct electric current to busbars under the cathode shell.

Advantageously, each VO can be of steel or copper or another good electrical conducting material, and according to one other aspect the cross section can be round or rectangular.

Preferably, in a situation where the material of the VO is not steel, then a protecting steel socket on the upper part below the plate can be applied to allow a fixation of the VO with good mechanical and electric contact and protection of the conductive material from aggressive chemicals or the VO can be protected by a steel tube reaching down to or close to the bottom of the steel shell.

Advantageously, the mounting of the VO allows pre-installation to the plate, e.g. by welding, or it can be mounted after the plate is installed into the lining.

Preferably, a sealing like at the HOs can be applied at the VOs.

Advantageously, the space around the VOs can be filled with loose refractory material or powder after the bottom shell sealing is applied. This filling can be applied from the side before the neighbouring cathode assembly is installed.

Preferably, if the length of the HOs is too long to allow a straight vertical placement of the cathode assembly, a swing in has to be applied. If VOs are present, some refractory bricks close to the centre of the lining have to be placed after installation of the plate to allow a horizontal shift of the assembly.

Advantageously, the difference in thermal expansion at operating temperatures between the copper connectors (HOs or VOs) can ensure high pressure at the contact with low electric resistance.

Preferably, the cathode element with collector plate can typically have less height than a design with traditional collector bars—when the same height for carbon is assumed—this extra space in height can be used for higher bottom insulation or higher cavity.

The present cathode design has shown to be very advantageous with regard to the magnetohydrodynamic stability of the cell it has been installed in, it has shown to have an improved life cycle and space usage and in operation, and it also represents a low cathode voltage drop with regard to a conventional cathode design.

These and further advantages will be achieved by the invention as defined in the accompanying claims.

The present invention will in the following be further described by figures and examples where;

FIG. 1 discloses in a first embodiment a divided cathode element, seen in perspective, where a collector plate is divided in two sections,

FIG. 2 discloses an embodiment of a non-divided cathode element in a cross-section view, where horizontal conductors extend into a collector plate at different lengths and further seen from one side, the element having a vertical current outlet,

FIG. 3 discloses a top-side view of the same cathode element as shown in FIG. 2,

FIG. 4 discloses an alternative embodiment of a cathode element without a vertical current outlet, where horizontal conductors extend into the collector plate at different lengths,

FIG. 5 discloses in a top-side part view of a collector plate like in FIG. 1, but the horizontal outlet extends to a delta-shaped conductor inside the plate,

FIG. 6 discloses in an enlarged view a cross-section through the cathode element of FIG. 2, seen from one end and discloses further details of one vertical current outlet,

FIG. 7 discloses in an enlarged view an alternative embodiment of the outlet as described in FIG. 6,

FIG. 8 is a principal sketch showing in a cross sectional view the main parts of a Hall-Héroult cell wherein a cathode element corresponding to that shown in FIG. 2 is included.

From FIG. 8 it can be seen a cross sectional view of the main parts of a Hall-Héroult cell where its superstructure includes alumina/fluoride hoppers, anode stubs, bus bars and feeding devices. Further, a pair of anodes partly covered by a crust is dipped into a liquid bath. Under the liquid bath there is shown a layer of liquid aluminium. The cathode is arranged below the liquid aluminium. The cathode comprises a carbonaceous body 4 arranged onto a collector plate 2. At each end of the collector plate there is arranged horizontal current outlets 5, 5′. It is also disclosed a vertical outlet 7. Various embodiments of cathode elements will be disclosed in more detail in the following.

FIG. 1 discloses a divided cathode element 1 seen in perspective. In this embodiment the collector plate consists of two sections 20, 20′. In the disclosed embodiment, collector plate sections 20, 20′ can be identical or not and will be described accordingly.

The collector plate section 20′ is provided in this example with six collector elements, 30, 30′ 30″, 30′″, 30″″, 30′″″ that are in electrical contact with the collector plate section 20′. Preferably, these parts are made out of a steel quality that can easily be welded, and preferably the parts are welded together. A cathode block can be rodded to the collector elements, in a similar manner as disclosed in WO2009/099335A1. The present solution may involve electric conductive particles or a contacting paste. The number of collector elements at the collector plate may differ from six as shown, for instance one to seven or even none.

At each outer end of the collector plate sections 20; 20′, there is arranged two horizontal current outlets 50, 51; 50′, 51′ respectively. The horizontal current outlets can be made out of conductors of a good conducting material like copper or copper alloy and further being, at least at its outlet ends, covered by a sheet material 60, 61; 60′, 61′, preferably made out of a metal such as steel. The horizontal current outlets 50, 51; 50′, 51′ with their corresponding conductors can be integrated in slots S, S′; S″, S′″ made in the corresponding collector plate sections 20; 20′. This integration may be based upon press-fit tolerances or pre-heated plate sections to use thermal expansion for a tight fit. However, any appropriate fixation including welding may be applied. The conducting material in the slots may be covered by a protective steel plate on the upper and lower side.

Further, close to the edge of the short and long sides of the collector plate sections, there can be arranged a flexible sealing rope or stopper plates (not shown) intended to facilitate the rodding of the plate to a carbonaceous body by means of electrically conductive metal particles. When rodding the cathode block to the cathode plate, the outer part of the carbonaceous material closer to the horizontal outlets can preferably be electrically insulated from the cathode plate, for instance 100 mm and up to 450 mm from the end of the cathode block and inwards to avoid high current densities at the upper surface of the cathode block close to the ends. The electric insulation can be asymmetric on each of the ends and also differ between the cathode elements in the cell.

In FIG. 2 it can be seen a second embodiment of a cathode element 1′ in a cross-section view seen from one side, where a carbonaceous body 4 is arranged onto a collector plate 2 which is not divided. In this embodiment the collector plate 2 has collector elements, where only one 3 is seen from the side. At each end of the collector plate 2 there is arranged horizontal current outlets 5, 5′. The horizontal current outlets can be made out of a copper material and being covered by a sheet material 6, 6′, preferably made out of a metal such as steel. It is also briefly disclosed a vertical outlet 7, that will be further described with reference to FIGS. 6 and 7.

The cross section of the horizontal outlets may be different at one end of the plate versus the other to compensate for different electric current path lengths of the conducting busbars to the next cell, e.g. for side-by-side arranged cells in a row of plural cells. The outlets on the upstream side could have a larger cross-section—either by a greater width or height or both—to reduce the electric resistance on that side of the cell and thus equalize the current distribution into the top of the cathode block surface. If the conductors of the horizontal outlets are of a better conducting material than the plate, they can be applied with different insertion length on each side of the plate when appropriate.

FIG. 3 discloses a top-side view of the same cathode as shown in FIG. 2, with the carbonaceous body 4 laying onto a collector plate 2 with one outlet on each side 5, 5′ covered by sheet material 6, 6′. Further, it is indicated a bore B in the collector plate for insertion of a thermocouple TC.

The embodiment shown in FIG. 4 relates to the same embodiment as shown in FIG. 2, however without a vertical outlet. It discloses a cathode element 1 in a cross-section view seen from one side, where a carbonaceous body 4 is arranged onto a collector plate 2 which is not divided, see below. In this embodiment the plate 2 has collector elements, where only one 3 is seen from the side. At each end of the collector plate 2 there is arranged horizontal current outlets 5, 5′. The conductors of the horizontal current outlets can be made out of a copper material and being covered by a sheet material 6, 6′, preferably made out of a metal such as steel. The dividing line D in the drawing indicates that the extension of the cathode element can be varied, i.e. also the intrusion length of the current conductors 5, 5′ in the plate 2 may vary depending upon the actual design.

The current conductors may in principle have a rectangular or round cross-section and as an alternative be out of any suitable electrical current conducting material.

FIG. 5 discloses partly one end of a collector plate 2 or similarly a collector plate section that may have one single horizontal current outlet 5 at its end which comprises a triangle or delta shaped electric conductor 51 made of copper or similar good conducting material to ensure a better distribution of the currents leaving the plate 2 and entering into the conductor 51 and further to its outlet 5, and by that reducing the electric resistance. The conductor 51 can be press-fit inserted into a recess of the plate 2, or attached to it by any appropriate means. In one alternative, the conductor could be cast into the recess, by for instance of melt copper. In case there is cast an extension beyond the recess outside the plate, it could be done by applying an appropriate mould or the similar.

FIG. 6 discloses further details of the vertical current outlet 7 as shown in FIG. 2 and represents an enlarged end-view of a cross-section through one end of the cathode of FIG. 2. A carbonaceous body 4 is resting onto a collector plate 2 having collector elements 3, 3′, 3″, 3′″, 3″″. The carbonaceous body has recesses or slots 9, 9′, 9″, 9′″, 9″″ complementary with said collector elements. The remaining space between the collector elements and the slots is filled with electric conductive material or particles. The collector elements are in this embodiment fixed to a metallic collector plate 2 that collects the current and secures stability.

The vertical outlet 7 comprises a socket 10 integrated with the collector plate 2 where a rod-shaped current conductor 11 can be attached to the socket 10. The conductor 11 can be made of a material with good electric conductivity like copper. The socket 10 can be made of a metallic material like steel and welded or press-fit to the collector plate 2. The vertical outlet can be placed in the centre of the plate or asymmetric towards one of the horizontal outlets to improve the magnetic field situation or to change the current distribution between horizontal and vertical outlets in a desired way.

Further, the socket 10 has an internal recess 17′ where an upper part 17 of the current conductor 11 has a shape complementary with said recess 17′ for fixation of said current conductor 11 to the socket 10. The upper part 17 of the current conductor 11 can be provided with threads mating corresponding threads in the upper part of the socket 10. The fixation can be optionally a press-fit (knock) fixation.

Further, in an embodiment or in addition, see FIG. 7, the socket 10′ may have internal threads 13′ at its outermost end for receiving a sleeve 12′ with complementary external threads 16′, wherein the sleeve surrounds the current conductor 11′ and where the end of the sleeve abuts an annular flange or ring 14′ at the current rod 11′ for forcing the rod 11′ into the socket 10′ when tightened. The current conductor 11′ is preferably made out of copper or an alloy thereof. The sleeve 12′ both serves for fixation and protection against reactions of conductor 11′ with liquids or volatiles from the process. Further, it is disclosed a bore B′ for insertion of a thermocouple TC′.

As an alternative to the internal thread 13′ a threaded bolt can be attached inside the top of the socket (not shown) and the conductor 11′ is fitted with a corresponding threaded bore to fix the conductor to the socket (similar to that shown in FIG. 6). A removable connection of the outlet might be needed to allow for a vertical outlet conductor to be attached after the cathode is placed with a swing-in movement on top of the bottom lining in the cell during installation.

Advantageously, the whole assembly with the carbonaceous body 4 and the collector plate 2 are tilted somewhat during the filling procedure of the particles, to allow the particles to fill the recess in a smooth and complete manner. Additionally some vibration might be applied to the plate or plate sections for homogeneous filling with the particles.

The recesses or slots 9 can be made in a green condition of the carbonaceous body by commonly used techniques or in a calcinated condition by commonly available process equipment. The geometry of the slots has to fit the plates.

It should be understood that the electrical conducting solids or particles can be of any appropriate metal such as steel, iron, copper, aluminium etc., or alloys of same. Further, the shape of the solids can be spherical, oval or elliptic, flaked, or have any appropriate shape. The size and particle distribution may vary. The maximum size will in general be restricted by the width of the space to be filled. A non-homogenous distribution of particle sizes may be convenient to obtain a compact filling as possible, with little space between the particles.

Apart from having good electrical conducting properties, the applied material should have good mechanical properties (crushing properties) and be able to sustain high temperatures. As mentioned later, magnetic properties may be advantageous.

Further, the size of said solids can be from 0.1 millimetres and close to the minimum opening between the carbonaceous body and conductor plate. Commonly, the size may be up to 2 millimetres.

Preferably there can be several thermocouples attached to or inserted into the cathode plate to monitor the temperature in the cathode. For instance, holes up to the center of the plate can be drilled in the cathode plate at appropriate locations for reception of thermocouples. The steel plate creates a protective housing for the thermocouples to survive the chemical aggressive environment during operation.

The insertion length of the horizontal outlets can preferably be limited in that it does not cover the central part of the cathode plate. The length of the insertion can for example be designed to reflect the existence of vertical outlets in that plate, and the path length of the current through the conductors to the next cell. On side-by-side arranged cells the length of the insertion can be made longer on the upstream side to balance the current pick-up in the cathode block to be more balanced.

Each cathode element can be fitted with horizontal outlets only for instance for end-to-end arranged cells or when there is no space for busbars under the cell, or with several horizontal outlets and one vertical outlet. To optimize the magnetic field, a configuration with one or two vertical outlets only and no horizontal outlet can be possible as well.

A combination of different plate configurations can be applied in one cell to create a favourable magnetic field from the electric current distribution or enhance the thermal properties of the cell by reducing the number of outlets where a heat loss is undesired, e.g. on the short ends of the cell which tend to be colder due to the nearby corners. Vertical outlets attached to only some plates can be beneficial to optimize the current flow and magnetic field. This may as well reduce the costs of the installation when the current distribution and magnetohydrodynamic stability of the cell is sufficient.

The claimed plate cathode has multiple advantages compared to a traditional design comprising a carbonaceous body with embedded collector bars:

-   -   The cathode voltage drop (CVD) is significantly lower due to the         number of outlets, material electric properties, better electric         contact due to initial mobility of particles, total surface of         contact resistance and shorter current paths from the existence         of vertical outlets     -   The current distribution into the top cathode block surface is         more homogeneous due to the plate geometry, conductance of         insertions, and existence of vertical outlets, thus avoiding         undesired, instability causing horizontal currents in the liquid         aluminium pad above the cathode block surface. The higher         stability of the cell can be used to reduce the cell voltage and         energy consumption further or increase the amperage and         production volume     -   Due to the above mentioned better current distribution, the         erosion of the carbonaceous material is more homogeneous thus         increasing the life time of the cell     -   The vertical space usage of the arrangement is less than with         conventional design, thus allowing for a lower cathode shell         or—if the shell height is kept, to use the extra space for         better bottom insulation, higher and longer-lasting cathode         blocks, or more height for liquid aluminium or bath     -   The design has a better ratio of electric to thermal         conductivity at the most critical locations of high current         density and heat flow, thus improving the energy efficiency of         the cell (less heat loss and lower cathode voltage drop CVD)     -   When retrofitted to an existing cell design, vertical outlets         according to the claims may allow to raise the amperage and thus         increase production per cell     -   Lower voltage drop (CVD), as less as 150 mV     -   Better current distribution into the cathode surface giving         improved MHD stability and thus options to reduce the ACD or         increase the amperage level by up to 15%     -   Less heat loss because of smaller cross-section and exposed         surface of HO and VO avoiding cold cathodes with bottom freeze,         specifically if the technology is used to reduce energy         consumption     -   Lower rodding cost as there is no cast iron     -   No risk of cracking of carbon block compared to cast-in         collector bars (cast iron)     -   Flexible installation of VOs after placing of the cathode blocks         in the lining     -   Better balancing of current flow to upstream/downstream/bottom         side giving better MHD stability     -   Less total height of the assembly giving space for more thermal         bottom insulation or larger cavity. This could be up to 150 mm     -   Longer life time of carbon cathode block at same assembly height         like traditional design with collector bars, as the height of         the usable carbon block can be up to 150 mm higher     -   Easier installation of thermocouples inside the plate due to         less deep drilling than in collector bars, or direct access from         bottom side 

1. A cathode element for an electrolysis cell of Hall-Héroult type for producing aluminium, comprising a carbonaceous body (4) of calcinated carbonaceous material connected with the upper side of a metallic collector plate (2), wherein a space between the said carbonaceous body (4) and the collector plate (2) being filled with an electric conductive material, preferably comprising conductive particles, wherein the collector plate (2) further comprises at least one horizontal current outlet (5, 5′) on at least one side and/or at least one vertical metallic current outlet (7) connected to the collector plate (2).
 2. The cathode element according to claim 1, wherein the carbonaceous body (4) is rodded to the collector plate (2) in a manner where the outer end part of the carbonaceous body (4) is electrically insulated from the collector plate (2), at a distance up to 450 mm from the end thereof and inwards.
 3. The cathode element according to claim 1, wherein the carbonaceous body (4) is rodded to the collector plate (2) in a manner where the outer end part of the carbonaceous body (4) is electrically insulated from the collector plate (2) at different lengths on both ends of the plate (asymmetric).
 4. The cathode element according to claim 1, wherein at least one thermocouple (TC) is inserted into a metallic component inside of or below the collector plate (2).
 5. The cathode element according to claim 1, wherein it comprises at least one horizontal current outlet (5; 50) integrated with the collector plate (2; 20).
 6. The cathode element according to claim 5, wherein the at least one horizontal current outlet (5; 50) is integrated in a slot (S) in the collector plate (2; 20).
 7. The cathode element according to claim 5, wherein the horizontal current outlet (5; 50) comprises one current conductor part (5; 50) that is integrated to the collector plate (2; 20) by a press-fit (knock) fixation in a recess of the collector plate (2; 20) that is complementary with the corresponding part of the conductor (5, 50).
 8. The cathode element according to claim 5, wherein the part of the current conductor (5; 50) integrated to the collector plate (2; 20) has a delta shaped part (51).
 9. The cathode element according to claim 5, wherein it comprises at least one horizontal current outlet (5, 5′) on each end being integrated with the collector plate (2).
 10. The cathode element according to claim 9, wherein the cross section of or the insertion length of the horizontal current outlet at one end is different of that of the other end (asymmetric).
 11. The cathode element according to claim 5, wherein the current outlet (5; 50) comprises a copper conductor preferably covered by a protective sheet (6; 60).
 12. The cathode element according to claim 1, wherein it comprises at least one vertical current outlet (7) arranged at the opposite side of the collector (2) plate than the said carbonaceous body (4).
 13. The cathode element according to claim 12, wherein the vertical outlet (7) comprises of a socket (10) integrated with the collector plate (2) wherein a rod-shaped current conductor (11) is attached to the socket (10).
 14. The cathode element according to claim 13, wherein the socket (10) is of a metallic material and further welded to the collector plate (2).
 15. The cathode element according to claim 13, wherein the socket (10) has an internal recess (17′) where an upper part (17) of the current conductor (11) has a shape complementary with said recess (17′) for fixation of said current conductor (11) to the socket (10).
 16. The cathode element according to claim 13, wherein the fixation is a press-fit (knock) fixation.
 17. The cathode element according to claim 13, wherein the socket (10) has internal threads 13 at its outermost end for receiving a sleeve (12′) with complementary external threads (16′), wherein the sleeve surrounds the current conductor (11) and where the end of the sleeve abuts an annular flange or ring (14′) at the current rod (11) for forcing the rod (11) into the socket (10) when tightened.
 18. The cathode element according to claim 13, wherein there is a threaded bolt (17) at the top of the socket communicating with a threaded bore (17′).
 19. The cathode element according to claim 12, wherein the current conductor (11) is made out of copper or an alloy thereof.
 20. The cathode element according to claim 1, wherein at least one metallic collector element (3) is arranged at the upper side of a metallic collector plate (2), where said collector element (3) is embedded in a corresponding recess (9) in the bottom part of said carbonaceous body (4), the recess being wider than the collector element and being filled with an electric conductive material comprising conductive particles.
 21. The cathode element according to claim 20, wherein there is one or more collector elements (3), preferably 3 to 7 being separated at a distance of typically 50 mm to 150 mm.
 22. The cathode element according to claim 20, wherein the at least one collector element(s) (3) is of same length or shorter length than the carbonaceous body (4).
 23. An electrolysis cell of Hall-Héroult type comprising several cathode elements as defined in c1aim 1, wherein a cell is built with several cathode elements and in a configuration of only the same elements.
 24. An electrolysis cell of Hall-Héroult type comprising several cathode elements as defined in c1aim 1, wherein a cell is built with several cathode elements and in a configuration of different elements. 